def DCCNN(band, imx, ncla1): input1 = Input(shape=(imx, imx, band)) # define network conv01 = Conv2D(128, kernel_size=(1, 1), padding='valid', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv02 = Conv2D(128, kernel_size=(3, 3), padding='valid', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv03 = Conv2D(128, kernel_size=(5, 5), padding='valid', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn1 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') bn2 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv0 = Conv2D(128, kernel_size=(1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv11 = Conv2D(128, kernel_size=(1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv12 = Conv2D(128, kernel_size=(1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv21 = Conv2D(128, kernel_size=(1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv22 = Conv2D(128, kernel_size=(1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv31 = Conv2D(128, kernel_size=(1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv32 = Conv2D(128, kernel_size=(1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv33 = Conv2D(128, kernel_size=(1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) fc1 = Dense(ncla1, activation='softmax', name='output1', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) # begin x1 = conv01(input1) x2 = conv02(input1) x3 = conv03(input1) x1 = MaxPooling2D(pool_size=(5, 5))(x1) x2 = MaxPooling2D(pool_size=(3, 3))(x2) x1 = concatenate([x1, x2, x3], axis=-1) x1 = Activation('relu')(x1) x1 = bn1(x1) x1 = conv0(x1) x11 = Activation('relu')(x1) x11 = bn2(x11) x11 = conv11(x11) x11 = Activation('relu')(x11) x11 = conv12(x11) x1 = Add()([x1, x11]) x11 = Activation('relu')(x1) x11 = conv21(x11) x11 = Activation('relu')(x11) x11 = conv22(x11) x1 = Add()([x1, x11]) x1 = Activation('relu')(x1) x1 = conv31(x1) x1 = Activation('relu')(x1) x1 = Dropout(0.5)(x1) x1 = conv32(x1) x1 = Activation('relu')(x1) x1 = Dropout(0.5)(x1) x1 = conv33(x1) x1 = Flatten()(x1) pre1 = fc1(x1) model1 = Model(inputs=input1, outputs=pre1) return model1
X_train, X_valid, y_train, y_valid = train_test_split(veri, labels, test_size=0.1) X_train = np.array(X_train).reshape(691, 8, 1) X_valid = np.array(X_valid).reshape(77, 8, 1) #Modelin Oluşturulması from tensorflow.keras.models import Sequential from tensorflow.keras.layers import Dense, Activation, Conv1D, Dropout, Flatten, MaxPooling1D model = Sequential() model = Sequential() model.add(Conv1D(512, 1, input_shape=(nb_features, 1))) model.add(Activation("relu")) model.add(MaxPooling1D(2)) model.add(Conv1D(256, 1)) model.add(Activation("relu")) model.add(MaxPooling1D(2)) #verilerlin %25 atıyoruz model.add(Dropout(0.25)) #verileri düzleştirme model.add(Flatten()) #Yapay Sinir Ağı model.add(Dense(2048, activation="relu")) model.add(Dense(1024, activation="relu")) #En son sonoflandırma yapalım. Sınıflandırma için softmax kullanılır model.add(Dense(nb_classes, activation="softmax")) model.summary()
def EEGNet_SSVEP(nb_classes = 12, Chans = 8, Samples = 256, dropoutRate = 0.5, kernLength = 256, F1 = 96, D = 1, F2 = 96, dropoutType = 'Dropout'): """ SSVEP Variant of EEGNet, as used in [1]. Inputs: nb_classes : int, number of classes to classify Chans, Samples : number of channels and time points in the EEG data dropoutRate : dropout fraction kernLength : length of temporal convolution in first layer F1, F2 : number of temporal filters (F1) and number of pointwise filters (F2) to learn. D : number of spatial filters to learn within each temporal convolution. dropoutType : Either SpatialDropout2D or Dropout, passed as a string. [1]. Waytowich, N. et. al. (2018). Compact Convolutional Neural Networks for Classification of Asynchronous Steady-State Visual Evoked Potentials. Journal of Neural Engineering vol. 15(6). http://iopscience.iop.org/article/10.1088/1741-2552/aae5d8 """ if dropoutType == 'SpatialDropout2D': dropoutType = SpatialDropout2D elif dropoutType == 'Dropout': dropoutType = Dropout else: raise ValueError('dropoutType must be one of SpatialDropout2D ' 'or Dropout, passed as a string.') input1 = Input(shape = (Chans, Samples, 1)) ################################################################## block1 = Conv2D(F1, (1, kernLength), padding = 'same', input_shape = (Chans, Samples, 1), use_bias = False)(input1) block1 = BatchNormalization()(block1) block1 = DepthwiseConv2D((Chans, 1), use_bias = False, depth_multiplier = D, depthwise_constraint = max_norm(1.))(block1) block1 = BatchNormalization()(block1) block1 = Activation('elu')(block1) block1 = AveragePooling2D((1, 4))(block1) block1 = dropoutType(dropoutRate)(block1) block2 = SeparableConv2D(F2, (1, 16), use_bias = False, padding = 'same')(block1) block2 = BatchNormalization()(block2) block2 = Activation('elu')(block2) block2 = AveragePooling2D((1, 8))(block2) block2 = dropoutType(dropoutRate)(block2) flatten = Flatten(name = 'flatten')(block2) dense = Dense(nb_classes, name = 'dense')(flatten) softmax = Activation('softmax', name = 'softmax')(dense) return Model(inputs=input1, outputs=softmax)
def __init__(self, input_size=512): ''' 输入部分, 训练时有除了input_image以外, 还有 overly_small_text_region_training_mask : 标记尺寸过小的文字, 避免干扰训练 text_region_boundary_training_mask: 标记文本框与score map的边界 target_score_map: grand truth score ''' input_image = Input(shape=(None, None, 3), name='input_image') overly_small_text_region_training_mask = Input( shape=(None, None, 1), name='overly_small_text_region_training_mask') text_region_boundary_training_mask = Input( shape=(None, None, 1), name='text_region_boundary_training_mask') target_score_map = Input(shape=(None, None, 1), name='target_score_map') resnet = MobileNetV2(input_tensor=input_image) x = resnet.get_layer('out_relu').output x = Lambda(resize_bilinear, name='resize_1')(x) x = concatenate([x, resnet.get_layer('block_13_expand_relu').output], axis=3) x = Conv2D(128, (1, 1), padding='same', kernel_regularizer=regularizers.l2(1e-5))(x) x = BatchNormalization(momentum=0.997, epsilon=1e-5, scale=True)(x) x = Activation('relu')(x) x = Conv2D(128, (3, 3), padding='same', kernel_regularizer=regularizers.l2(1e-5))(x) x = BatchNormalization(momentum=0.997, epsilon=1e-5, scale=True)(x) x = Activation('relu')(x) x = Lambda(resize_bilinear, name='resize_2')(x) x = concatenate([x, resnet.get_layer('block_6_expand_relu').output], axis=3) x = Conv2D(64, (1, 1), padding='same', kernel_regularizer=regularizers.l2(1e-5))(x) x = BatchNormalization(momentum=0.997, epsilon=1e-5, scale=True)(x) x = Activation('relu')(x) x = Conv2D(64, (3, 3), padding='same', kernel_regularizer=regularizers.l2(1e-5))(x) x = BatchNormalization(momentum=0.997, epsilon=1e-5, scale=True)(x) x = Activation('relu')(x) x = Lambda(resize_bilinear, name='resize_3')(x) x = concatenate([x, resnet.get_layer('block_3_expand_relu').output], axis=3) x = Conv2D(32, (1, 1), padding='same', kernel_regularizer=regularizers.l2(1e-5))(x) x = BatchNormalization(momentum=0.997, epsilon=1e-5, scale=True)(x) x = Activation('relu')(x) x = Conv2D(32, (3, 3), padding='same', kernel_regularizer=regularizers.l2(1e-5))(x) x = BatchNormalization(momentum=0.997, epsilon=1e-5, scale=True)(x) x = Activation('relu')(x) x = Conv2D(32, (3, 3), padding='same', kernel_regularizer=regularizers.l2(1e-5))(x) x = BatchNormalization(momentum=0.997, epsilon=1e-5, scale=True)(x) x = Activation('relu')(x) pred_score_map = Conv2D(1, (1, 1), activation=tf.nn.sigmoid, name='pred_score_map')(x) rbox_geo_map = Conv2D(4, (1, 1), activation=tf.nn.sigmoid, name='rbox_geo_map')(x) rbox_geo_map = Lambda(lambda x: x * input_size)(rbox_geo_map) angle_map = Conv2D(1, (1, 1), activation=tf.nn.sigmoid, name='rbox_angle_map')(x) angle_map = Lambda(lambda x: (x - 0.5) * np.pi / 2)(angle_map) pred_geo_map = concatenate([rbox_geo_map, angle_map], axis=3, name='pred_geo_map') model = Model(inputs=[ input_image, overly_small_text_region_training_mask, text_region_boundary_training_mask, target_score_map ], outputs=[pred_score_map, pred_geo_map]) self.model = model self.input_image = input_image self.overly_small_text_region_training_mask = overly_small_text_region_training_mask self.text_region_boundary_training_mask = text_region_boundary_training_mask self.target_score_map = target_score_map self.pred_score_map = pred_score_map self.pred_geo_map = pred_geo_map
def resnet_v1(input_shape, depth, num_classes=10): """ResNet Version 1 Model builder [a] Stacks of 2 x (3 x 3) Conv2D-BN-ReLU Last ReLU is after the shortcut connection. At the beginning of each stage, the feature map size is halved (downsampled) by a convolutional layer with strides=2, while the number of filters is doubled. Within each stage, the layers have the same number filters and the same number of filters. Features maps sizes: stage 0: 32x32, 16 stage 1: 16x16, 32 stage 2: 8x8, 64 The Number of parameters is approx the same as Table 6 of [a]: ResNet20 0.27M ResNet32 0.46M ResNet44 0.66M ResNet56 0.85M ResNet110 1.7M Args: input_shape (tensor): shape of input image tensor depth (int): number of core convolutional layers num_classes (int): number of classes (CIFAR10 has 10) Returns: model (Model): Keras model instance """ if (depth - 2) % 6 != 0: raise ValueError('depth should be 6n+2 (eg 20, 32, 44 in [a])') # Start model definition. num_filters = 16 num_res_blocks = int((depth - 2) / 6) inputs = Input(shape=input_shape) x = resnet_layer(inputs=inputs) # Instantiate the stack of residual units for stack in range(3): for res_block in range(num_res_blocks): strides = 1 if stack > 0 and res_block == 0: # first layer but not first stack strides = 2 # downsample y = resnet_layer(inputs=x, num_filters=num_filters, strides=strides) y = resnet_layer(inputs=y, num_filters=num_filters, activation=None) if stack > 0 and res_block == 0: # first layer but not first stack # linear projection residual shortcut connection to match # changed dims x = resnet_layer(inputs=x, num_filters=num_filters, kernel_size=1, strides=strides, activation=None, batch_normalization=False) x = keras.layers.add([x, y]) x = Activation('relu')(x) num_filters *= 2 # Add classifier on top. # v1 does not use BN after last shortcut connection-ReLU x = AveragePooling2D(pool_size=x.shape[1:3])(x) y = Flatten()(x) outputs = Dense(num_classes, activation='softmax', kernel_initializer='he_normal')(y) # Instantiate model. model = Model(inputs=inputs, outputs=outputs) return model
def HRNetResidual(input_shape=(128, 128, 3), num_keypoints=20): """Instantiates HRNET Residual model # Arguments input_shape: List of three elements e.g. ''(H, W, 3)'' num_keypoints: Int. # Returns Tensorflow-Keras model. # References -[High-Resolution Representations for Labeling Pixels and Regions](https://arxiv.org/pdf/1904.04514.pdf) """ # stem inputs = Input(shape=input_shape, name='image') x1 = stem(inputs, 64) x1 = Conv2D(64 * 4, 1, padding='same', use_bias=False)(x1) x1 = BatchNormalization()(x1) for block in range(4): x1 = bottleneck(x1) # stage I x1 = Conv2D(32, 3, padding='same', use_bias=False)(x1) x1 = BatchNormalization()(x1) x1 = Activation('relu')(x1) x2 = transition_block(x1, 2) # stage II for block in range(4): x1 = residual_block(x1, 32) x2 = residual_block(x2, 64) x1, x2 = fuse([x1, x2]) x3 = transition_block(x2, 2) # stage III for module in range(4): for block in range(4): x1 = residual_block(x1, 32) x2 = residual_block(x2, 64) x3 = residual_block(x3, 128) x1, x2, x3 = fuse([x1, x2, x3]) x4 = transition_block(x3, 2) # stage IV for module in range(3): for block in range(4): x1 = residual_block(x1, 32) x2 = residual_block(x2, 64) x3 = residual_block(x3, 128) x4 = residual_block(x4, 256) x1, x2, x3, x4 = fuse([x1, x2, x3, x4]) # head x2 = UpSampling2D(size=(2, 2))(x2) x3 = UpSampling2D(size=(4, 4))(x3) x4 = UpSampling2D(size=(8, 8))(x4) x = Concatenate()([x1, x2, x3, x4]) x = Conv2D(480, 1)(x) x = BatchNormalization(epsilon=1.001e-5)(x) x = Activation('relu')(x) x = Conv2D(num_keypoints, 1)(x) # extra x = BatchNormalization(epsilon=1.001e-5)(x) x = Activation('relu')(x) x = UpSampling2D(size=(4, 4), interpolation='bilinear')(x) x = Permute([3, 1, 2])(x) x = Reshape([num_keypoints, input_shape[0] * input_shape[1]])(x) x = Activation('softmax')(x) x = Reshape([num_keypoints, input_shape[0], input_shape[1]])(x) outputs = ExpectedValue2D(name='keypoints')(x) model = Model(inputs, outputs, name='hrnet-residual') return model
def DilatedNet(img_height, img_width, nclasses, use_ctx_module=False, bn=False): print('. . . . .Building DilatedNet. . . . .') def bilinear_upsample(image_tensor): upsampled = tf.image.resize_bilinear(image_tensor, size=(img_height, img_width)) return upsampled def conv_block(conv_layers, tensor, nfilters, size=3, name='', padding='same', dilation_rate=1, pool=False): if dilation_rate == 1: conv_type = 'conv' else: conv_type = 'dilated_conv' for i in range(conv_layers): tensor = Conv2D(nfilters, size, padding=padding, use_bias=False, dilation_rate=dilation_rate, name=f'block{name}_{conv_type}{i+1}')(tensor) if bn: tensor = BatchNormalization( name=f'block{name}_bn{i+1}')(tensor) tensor = Activation('relu', name=f'block{name}_relu{i+1}')(tensor) if pool: tensor = MaxPooling2D(2, name=f'block{name}_pool')(tensor) return tensor nfilters = 64 img_input = Input(shape=(img_height, img_width, 3)) x = conv_block(conv_layers=2, tensor=img_input, nfilters=nfilters * 1, size=3, pool=True, name=1) x = conv_block(conv_layers=2, tensor=x, nfilters=nfilters * 2, size=3, pool=True, name=2) x = conv_block(conv_layers=3, tensor=x, nfilters=nfilters * 4, size=3, pool=True, name=3) x = conv_block(conv_layers=3, tensor=x, nfilters=nfilters * 8, size=3, name=4) x = conv_block(conv_layers=3, tensor=x, nfilters=nfilters * 8, size=3, dilation_rate=2, name=5) x = conv_block(conv_layers=1, tensor=x, nfilters=nfilters * 64, size=7, dilation_rate=4, name='_FCN1') x = Dropout(0.5)(x) x = conv_block(conv_layers=1, tensor=x, nfilters=nfilters * 64, size=1, name='_FCN2') x = Dropout(0.5)(x) x = Conv2D(filters=nclasses, kernel_size=1, padding='same', name=f'frontend_output')(x) if use_ctx_module: x = conv_block(conv_layers=2, tensor=x, nfilters=nclasses * 2, size=3, name='_ctx1') x = conv_block(conv_layers=1, tensor=x, nfilters=nclasses * 4, size=3, name='_ctx2', dilation_rate=2) x = conv_block(conv_layers=1, tensor=x, nfilters=nclasses * 8, size=3, name='_ctx3', dilation_rate=4) x = conv_block(conv_layers=1, tensor=x, nfilters=nclasses * 16, size=3, name='_ctx4', dilation_rate=8) x = conv_block(conv_layers=1, tensor=x, nfilters=nclasses * 32, size=3, name='_ctx5', dilation_rate=16) x = conv_block(conv_layers=1, tensor=x, nfilters=nclasses * 32, size=3, name='_ctx7') x = Conv2D(filters=nclasses, kernel_size=1, padding='same', name=f'ctx_output')(x) x = Lambda(bilinear_upsample, name='bilinear_upsample')(x) x = Reshape((img_height * img_width, nclasses))(x) x = Activation('softmax', name='final_softmax')(x) model = Model(inputs=img_input, outputs=x, name='DilatedNet') print('. . . . .Building network successful. . . . .') return model
def resnet_v1_eembc(input_shape=[32, 32, 3], num_classes=10, num_filters=[16, 32, 64], kernel_sizes=[3, 1], strides=[1, 2], l1p=1e-4, l2p=0): # Input layer, change kernel size to 7x7 and strides to 2 for an official resnet inputs = Input(shape=input_shape) x = Conv2D(num_filters[0], kernel_size=kernel_sizes[0], strides=strides[0], padding='same', kernel_initializer='he_normal', kernel_regularizer=l1_l2(l1=l1p, l2=l2p))(inputs) x = BatchNormalization()(x) x = Activation('relu')(x) # First stack # Weight layers y = Conv2D(num_filters[0], kernel_size=kernel_sizes[0], strides=strides[0], padding='same', kernel_initializer='he_normal', kernel_regularizer=l1_l2(l1=l1p, l2=l2p))(x) y = BatchNormalization()(y) y = Activation('relu')(y) y = Conv2D(num_filters[0], kernel_size=kernel_sizes[0], strides=strides[0], padding='same', kernel_initializer='he_normal', kernel_regularizer=l1_l2(l1=l1p, l2=l2p))(y) y = BatchNormalization()(y) # Overall residual, connect weight layer and identity paths x = Add()([x, y]) x = Activation('relu')(x) # Second stack # Weight layers y = Conv2D(num_filters[1], kernel_size=kernel_sizes[0], strides=strides[1], padding='same', kernel_initializer='he_normal', kernel_regularizer=l1_l2(l1=l1p, l2=l2p))(x) y = BatchNormalization()(y) y = Activation('relu')(y) y = Conv2D(num_filters[1], kernel_size=kernel_sizes[0], strides=strides[0], padding='same', kernel_initializer='he_normal', kernel_regularizer=l1_l2(l1=l1p, l2=l2p))(y) y = BatchNormalization()(y) # Adjust for change in dimension due to stride in identity x = Conv2D(num_filters[1], kernel_size=kernel_sizes[1], strides=strides[1], padding='same', kernel_initializer='he_normal', kernel_regularizer=l1_l2(l1=l1p, l2=l2p))(x) # Overall residual, connect weight layer and identity paths x = Add()([x, y]) x = Activation('relu')(x) # Third stack # Weight layers y = Conv2D(num_filters[2], kernel_size=kernel_sizes[0], strides=strides[1], padding='same', kernel_initializer='he_normal', kernel_regularizer=l1_l2(l1=l1p, l2=l2p))(x) y = BatchNormalization()(y) y = Activation('relu')(y) y = Conv2D(num_filters[2], kernel_size=kernel_sizes[0], strides=strides[0], padding='same', kernel_initializer='he_normal', kernel_regularizer=l1_l2(l1=l1p, l2=l2p))(y) y = BatchNormalization()(y) # Adjust for change in dimension due to stride in identity x = Conv2D(num_filters[2], kernel_size=kernel_sizes[1], strides=strides[1], padding='same', kernel_initializer='he_normal', kernel_regularizer=l1_l2(l1=l1p, l2=l2p))(x) # Overall residual, connect weight layer and identity paths x = Add()([x, y]) x = Activation('relu')(x) # Final classification layer. pool_size = int(np.amin(x.shape[1:3])) x = AveragePooling2D(pool_size=pool_size)(x) y = Flatten()(x) outputs = Dense(num_classes, activation='softmax', kernel_initializer='he_normal')(y) # Instantiate model. model = Model(inputs=inputs, outputs=outputs) return model
def fully_convolutional_resnet50( input_shape, num_classes=1000, pretrained_resnet=True, use_bias=True, ): # init input layer img_input = Input(shape=input_shape) # define basic model pipeline x = ZeroPadding2D(padding=((3, 3), (3, 3)), name="conv1_pad")(img_input) x = Conv2D(64, 7, strides=2, use_bias=use_bias, name="conv1_conv")(x) x = BatchNormalization(axis=3, epsilon=1.001e-5, name="conv1_bn")(x) x = Activation("relu", name="conv1_relu")(x) x = ZeroPadding2D(padding=((1, 1), (1, 1)), name="pool1_pad")(x) x = MaxPooling2D(3, strides=2, name="pool1_pool")(x) # the sequence of stacked residual blocks x = stack1(x, 64, 3, stride1=1, name="conv2") x = stack1(x, 128, 4, name="conv3") x = stack1(x, 256, 6, name="conv4") x = stack1(x, 512, 3, name="conv5") # add avg pooling layer after feature extraction layers x = AveragePooling2D(pool_size=7)(x) # add final convolutional layer conv_layer_final = Conv2D( filters=num_classes, kernel_size=1, use_bias=use_bias, name="last_conv", )(x) # configure fully convolutional ResNet50 model model = training.Model(img_input, x) # load model weights if pretrained_resnet: model_name = "resnet50" # configure full file name file_name = model_name + "_weights_tf_dim_ordering_tf_kernels_notop.h5" # get the file hash from TF WEIGHTS_HASHES file_hash = WEIGHTS_HASHES[model_name][1] weights_path = data_utils.get_file( file_name, BASE_WEIGHTS_PATH + file_name, cache_subdir="models", file_hash=file_hash, ) model.load_weights(weights_path) # form final model model = training.Model(inputs=model.input, outputs=[conv_layer_final]) if pretrained_resnet: # get model with the dense layer for further FC weights extraction resnet50_extractor = ResNet50( include_top=True, weights="imagenet", classes=num_classes, ) # set ResNet50 FC-layer weights to final convolutional layer set_conv_weights(model=model, feature_extractor=resnet50_extractor) return model
def build_model(img_shape: Tuple[int, int, int], num_classes: int, optimizer: tf.keras.optimizers.Optimizer, learning_rate: float, filter_block1: int, kernel_size_block1: int, filter_block2: int, kernel_size_block2: int, filter_block3: int, kernel_size_block3: int, dense_layer_size: int, kernel_initializer: tf.keras.initializers.Initializer, activation_cls: tf.keras.layers.Activation, dropout_rate: float, use_batch_normalization: bool, use_dense: bool, use_global_pooling: bool) -> Model: input_img = Input(shape=img_shape) x = Conv2D(filters=filter_block1, kernel_size=kernel_size_block1, padding="same", kernel_initializer=kernel_initializer, name="heatmap1")(input_img) if use_batch_normalization: x = BatchNormalization()(x) x = activation_cls(x) x = Conv2D(filters=filter_block1, kernel_size=kernel_size_block1, padding="same", kernel_initializer=kernel_initializer)(x) if use_batch_normalization: x = BatchNormalization()(x) if dropout_rate: x = Dropout(rate=dropout_rate)(x) x = activation_cls(x) x = MaxPool2D()(x) x = Conv2D(filters=filter_block2, kernel_size=kernel_size_block2, padding="same", kernel_initializer=kernel_initializer)(x) if use_batch_normalization: x = BatchNormalization()(x) x = activation_cls(x) x = Conv2D(filters=filter_block2, kernel_size=kernel_size_block2, padding="same", kernel_initializer=kernel_initializer)(x) if use_batch_normalization: x = BatchNormalization()(x) if dropout_rate: x = Dropout(rate=dropout_rate)(x) x = activation_cls(x) x = MaxPool2D()(x) x = Conv2D(filters=filter_block3, kernel_size=kernel_size_block3, padding="same", kernel_initializer=kernel_initializer)(x) if use_batch_normalization: x = BatchNormalization()(x) x = activation_cls(x) x = Conv2D(filters=filter_block3, kernel_size=kernel_size_block3, padding="same", kernel_initializer=kernel_initializer)(x) if use_batch_normalization: x = BatchNormalization()(x) if dropout_rate: x = Dropout(rate=dropout_rate)(x) x = activation_cls(x) x = MaxPool2D()(x) if use_global_pooling: x = GlobalAveragePooling2D()(x) else: x = Flatten()(x) if use_dense: x = Dense(units=dense_layer_size, kernel_initializer=kernel_initializer)(x) if use_batch_normalization: x = BatchNormalization()(x) x = activation_cls(x) x = Dense(units=num_classes, kernel_initializer=kernel_initializer)(x) y_pred = Activation("softmax")(x) model = Model(inputs=[input_img], outputs=[y_pred]) opt = optimizer(learning_rate=learning_rate) model.compile(loss="categorical_crossentropy", optimizer=opt, metrics=["accuracy"]) return model
def _bn_relu(input): """Helper to build a BN -> relu block """ norm = BatchNormalization(axis=CHANNEL_AXIS)(input) return Activation("relu")(norm)
def DeepSTN( H=32, W=32, channel=2, #H-map_height W-map_width channel-map_channel c=3, p=1, t=1, #c-closeness p-period t-trend pre_F=64, conv_F=64, R_N=2, #pre_F-prepare_conv_featrue conv_F-resnet_conv_featrue R_N-resnet_number is_plus=True, #use ResPlus or mornal convolution is_plus_efficient=False, #use the efficient version of ResPlus plus=8, rate=2, #rate-pooling_rate is_pt=True, #use PoI and Time or not P_N=9, T_F=31, PT_F=9, T=24, #P_N-poi_number T_F-time_feature PT_F-poi_time_feature T-T_times/day drop=0, is_summary=True, #show detail lr=0.0002, kernel1=1, #kernel1 decides whether early-fusion uses conv_unit0 or conv_unit1, 1 recommended isPT_F=1 ): #isPT_F decides whether PT_model uses one more Conv after multiplying PoI and Time, 1 recommended all_channel = channel * (c + p + t) cut0 = int(0) cut1 = int(cut0 + channel * c) cut2 = int(cut1 + channel * p) cut3 = int(cut2 + channel * t) cpt_input = Input(shape=(H, W, all_channel)) c_input = Lambda(cpt_slice, arguments={'h1': cut0, 'h2': cut1})(cpt_input) p_input = Lambda(cpt_slice, arguments={'h1': cut1, 'h2': cut2})(cpt_input) t_input = Lambda(cpt_slice, arguments={'h1': cut2, 'h2': cut3})(cpt_input) c_out1 = Conv2D(filters=pre_F, kernel_size=(1, 1), padding="same")(c_input) p_out1 = Conv2D(filters=pre_F, kernel_size=(1, 1), padding="same")(p_input) t_out1 = Conv2D(filters=pre_F, kernel_size=(1, 1), padding="same")(t_input) # print(t_out1.shape) if is_pt: poi_in = Input(shape=(P_N, H, W)) # T_times/day + 7days/week time_in = Input(shape=(T + 7, H, W)) PT_model = PT_trans('PT_trans', P_N, PT_F, T, T_F, H, W, isPT_F) poi_time = PT_model([poi_in, time_in]) cpt_con1 = Concatenate(axis=-1)([c_out1, p_out1, t_out1, poi_time]) # print("="*10) # print(c_out1.shape,p_out1.shape,t_out1.shape,poi_time.shape) # print(cpt_con1.shape) if kernel1: cpt = conv_unit1(pre_F * 3 + PT_F * isPT_F + P_N * (not isPT_F), conv_F, drop, H, W)(cpt_con1) else: cpt = conv_unit0(pre_F * 3 + PT_F * isPT_F + P_N * (not isPT_F), conv_F, drop, H, W)(cpt_con1) else: cpt_con1 = Concatenate(axis=1)([c_out1, p_out1, t_out1]) if kernel1: cpt = conv_unit1(pre_F * 3, conv_F, drop, H, W)(cpt_con1) else: cpt = conv_unit0(pre_F * 3, conv_F, drop, H, W)(cpt_con1) if is_plus: if is_plus_efficient: for i in range(R_N): cpt = Res_plus_E('Res_plus_' + str(i + 1), conv_F, plus, rate, drop, H, W)(cpt) else: for i in range(R_N): cpt = Res_plus('Res_plus_' + str(i + 1), conv_F, plus, rate, drop, H, W)(cpt) else: for i in range(R_N): cpt = Res_normal('Res_normal_' + str(i + 1), conv_F, drop, H, W)(cpt) cpt_conv2 = Activation('relu')(cpt) cpt_out2 = BatchNormalization()(cpt_conv2) cpt_conv1 = Dropout(drop)(cpt_out2) cpt_conv1 = Conv2D(filters=channel, kernel_size=(1, 1), padding="same")(cpt_conv1) cpt_out1 = Activation('tanh')(cpt_conv1) if is_pt: DeepSTN_model = Model(inputs=[cpt_input, poi_in, time_in], outputs=cpt_out1) else: DeepSTN_model = Model(inputs=cpt_input, outputs=cpt_out1) DeepSTN_model.compile(loss='mse', optimizer='Adam', metrics=['mae']) DeepSTN_model.summary() return DeepSTN_model
def create_network(n_commands, n_value1, n_durations, embed_size=100, rnn_units=256, use_attention=False): """ create the structure of the neural network """ commands_in = Input(shape=(None, ), name="commands_channels_in") value1_in = Input(shape=(None, ), name="values1_in") durations_in = Input(shape=(None, ), name="durations_in") x1 = Embedding(n_commands, embed_size)(commands_in) x2 = Embedding(n_value1, embed_size)(value1_in) x3 = Embedding(n_durations, embed_size)(durations_in) x = Concatenate()([x1, x2, x3]) x = LSTM(rnn_units, return_sequences=True)(x) #x = Dropout(0.2)(x) if use_attention: x = LSTM(rnn_units, return_sequences=True)(x) #x = Dropout(0.2)(x) e = Dense(1, activation='tanh')(x) e = Reshape([-1])(e) alpha = Activation('softmax')(e) alpha_repeated = Permute([2, 1])(RepeatVector(rnn_units)(alpha)) c = Multiply()([x, alpha_repeated]) c = Lambda(lambda xin: K.sum(xin, axis=1), output_shape=(rnn_units, ))(c) else: c = LSTM(rnn_units)(x) #c = Dropout(0.2)(c) commands_out = Dense(n_commands, activation='softmax', name='commands_channels_out')(c) value1_out = Dense(n_value1, activation='softmax', name='values1_out')(c) durations_out = Dense(n_durations, activation='softmax', name='durations_out')(c) model = Model([commands_in, value1_in, durations_in], [commands_out, value1_out, durations_out]) if use_attention: att_model = Model([commands_in, value1_in, durations_in], alpha) else: att_model = None opti = RMSprop(lr=0.005) model.compile(loss=[ 'categorical_crossentropy', 'categorical_crossentropy', 'categorical_crossentropy' ], optimizer=opti) return model, att_model
def resnet99(band, ncla1): input1 = Input(shape=(9, 9, band)) # define network conv0x = Conv2D(32, kernel_size=(3, 3), padding='valid', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv0 = Conv2D(32, kernel_size=(3, 3), padding='valid', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn11 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv11 = Conv2D(64, kernel_size=(3, 3), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv12 = Conv2D(64, kernel_size=(3, 3), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn21 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv21 = Conv2D(64, kernel_size=(3, 3), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv22 = Conv2D(64, kernel_size=(3, 3), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) fc1 = Dense(ncla1, activation='softmax', name='output1', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) # x1 x1 = conv0(input1) x1x = conv0x(input1) # x1 = MaxPooling2D(pool_size=(2,2))(x1) # x1x = MaxPooling2D(pool_size=(2,2))(x1x) x1 = concatenate([x1, x1x], axis=-1) x11 = bn11(x1) x11 = Activation('relu')(x11) x11 = conv11(x11) x11 = Activation('relu')(x11) x11 = conv12(x11) x1 = Add()([x1, x11]) # x11 = bn21(x1) # x11 = Activation('relu')(x11) # x11 = conv21(x11) # x11 = Activation('relu')(x11) # x11 = conv22(x11) # x1 = Add()([x1,x11]) x1 = Flatten()(x1) pre1 = fc1(x1) model1 = Model(inputs=input1, outputs=pre1) return model1
valid_set = test_datagen.flow_from_directory('images/validation', target_size = (48,48), batch_size = 32, color_mode='grayscale', class_mode = 'categorical') # number of possible label values n = 7 #print(dir(trainig_set)) # Initialising the CNN model = Sequential() # 1 - Convolution model.add(Conv2D(32,(3,3), padding='same', input_shape=(48, 48,1))) model.add(Activation('relu')) model.add(BatchNormalization()) model.add(MaxPooling2D(pool_size=(2, 2))) model.add(Dropout(0.25)) # 2nd Convolution layer model.add(Conv2D(64,(5,5), padding='same')) model.add(Activation('relu')) model.add(BatchNormalization()) model.add(MaxPooling2D(pool_size=(2, 2))) model.add(Dropout(0.25)) # 3rd Convolution layer model.add(Conv2D(128,(3,3), padding='same')) model.add(Activation('relu')) model.add(BatchNormalization())
save_dir = os.path.join(os.getcwd(), "..", "saved_models") save_dir = os.path.abspath(save_dir) model_name = "dropout_rate_025.h5" print(model_name) (x_train, y_train), (x_test, y_test) = cifar10.load_data() x_train = x_train.astype('float32') x_test = x_test.astype('float32') x_train = x_train / 255 x_test = x_test / 255 y_train = keras.utils.to_categorical(y_train, classes) y_test = keras.utils.to_categorical(y_test, classes) model = Sequential() model.add(Conv2D(32, (3, 3), padding="SAME", input_shape=x_train.shape[1:])) model.add(Activation("relu")) model.add(Conv2D(32, (3, 3))) model.add(Activation("relu")) model.add(MaxPooling2D(pool_size=(2, 2))) model.add(Dropout(dropout_rate)) model.add(Conv2D(64, (3, 3), padding="SAME")) model.add(Activation("relu")) model.add(Conv2D(64, (3, 3))) model.add(Activation("relu")) model.add(MaxPooling2D(pool_size=(2, 2))) model.add(Dropout(dropout_rate)) model.add(Flatten()) model.add(Dense(512)) model.add(Activation("relu"))
def HRNetDense(input_shape=(128, 128, 3), num_keypoints=20, growth_rate=4): # stem inputs = Input(shape=input_shape) x1 = stem(inputs, 64) x1 = Conv2D(64 * 4, 1, padding='same', use_bias=False)(x1) x1 = BatchNormalization()(x1) for block in range(4): x1 = bottleneck(x1) # stage I x1 = Conv2D(32, 3, padding='same', use_bias=False)(x1) x1 = BatchNormalization()(x1) x1 = Activation('relu')(x1) x2 = transition_block(x1, 2) print('stage 1', x1.shape, x2.shape) # stage II x1 = dense_block(x1, 4, growth_rate) x2 = dense_block(x2, 4, growth_rate) x1, x2 = fuse([x1, x2]) x3 = transition_block(x2, 0.5) print('stage 2', x1.shape, x2.shape, x3.shape) # stage III x1 = dense_block(x1, 4, growth_rate) x2 = dense_block(x2, 4, growth_rate) x3 = dense_block(x3, 4, growth_rate) x1, x2, x3 = fuse([x1, x2, x3]) x4 = transition_block(x3, 0.5) print('stage 3', x1.shape, x2.shape, x3.shape, x4.shape) # stage IV x1 = dense_block(x1, 3, growth_rate) x2 = dense_block(x2, 3, growth_rate) x3 = dense_block(x3, 3, growth_rate) x4 = dense_block(x4, 3, growth_rate) x1, x2, x3, x4 = fuse([x1, x2, x3, x4]) print('stage 4', x1.shape, x2.shape, x3.shape, x4.shape) x2 = UpSampling2D(size=(2, 2))(x2) x3 = UpSampling2D(size=(4, 4))(x3) x4 = UpSampling2D(size=(8, 8))(x4) x = Concatenate()([x1, x2, x3, x4]) # head x = Conv2D(480, 1)(x) x = BatchNormalization(epsilon=1.001e-5)(x) x = Activation('relu')(x) x = Conv2D(num_keypoints, 1)(x) # extra x = BatchNormalization(epsilon=1.001e-5)(x) x = Activation('relu')(x) x = UpSampling2D(size=(4, 4), interpolation='bilinear')(x) x = Permute([3, 1, 2])(x) x = Reshape([num_keypoints, input_shape[0] * input_shape[1]])(x) x = Activation('softmax')(x) x = Reshape([num_keypoints, input_shape[0], input_shape[1]])(x) outputs = ExpectedValue2D(name='expected_uv')(x) model = Model(inputs, outputs, name='hrnet-dense') return model
def Make_SingleNode_Model( input_shape, n_contr=2, #number of feature to contract in each site activation=None, #activcation function tu use use_batch_norm=False, #use (or not) batch normalization bond_dim=10, #boind dimension of the layers verbose=False, #verbosity, print the inital configuration use_reg=True #use (or not) kernel regularization ): KER_REG_L2 = 1.0e-4 #layer parameter regualrization n_layers = int(math.log(input_shape[0], n_contr)) #number of layers to create if verbose: print("input_shape", input_shape) print("n_contr", n_contr) print("n_layers", n_layers) tn_model = Sequential() #if the batch normalization is required the architecture has to be created step by step if use_batch_norm: #first layer, input shape is required and parameter tn_model.add( TTN_SingleNode( bond_dim=bond_dim, #bond dimension of the weights n_contraction= n_contr, #number of feature to contract to each weight tensor input_shape=input_shape, kernel_regularizer=regularizers.l2(KER_REG_L2) if use_reg else None #use regularization if specified )) #add batch normalization after the layer but before the activation tn_model.add( BatchNormalization(epsilon=1e-06, momentum=0.9, weights=None)) #if required use activation function if activation is not None: tn_model.add(Activation(activation)) #intermediate layers, same as before but withoput specifing input shape for _ in range(n_layers - 2): tn_model.add( TTN_SingleNode(bond_dim=bond_dim, n_contraction=n_contr, kernel_regularizer=regularizers.l2(KER_REG_L2) if use_reg else None)) tn_model.add( BatchNormalization(epsilon=1e-06, momentum=0.9, weights=None)) if activation is not None: tn_model.add(Activation(activation)) #last layer with bond dimension 1 tn_model.add( TTN_SingleNode( bond_dim=1, #bond dimension must be one to obtain a single value use_bias=True, n_contraction=n_contr, input_shape=input_shape, kernel_regularizer=regularizers.l2(KER_REG_L2) if use_reg else None)) tn_model.add( BatchNormalization(epsilon=1e-06, momentum=0.9, weights=None)) #activation must be used to interpret results as a probability tn_model.add(Activation('sigmoid')) #without batch normalization the activation can be directly included inside the model creation else: #first layer tn_model.add( TTN_SingleNode( bond_dim=bond_dim, #bond dimension activation=activation, #activation function input_shape=input_shape, #input shape n_contraction=n_contr, #contraction per site kernel_regularizer=regularizers.l2(KER_REG_L2) if use_reg else None #regularization )) #intermediate layers, same as previous layer but without input shape required for _ in range(n_layers - 2): tn_model.add( TTN_SingleNode(bond_dim=bond_dim, activation=activation, n_contraction=n_contr, kernel_regularizer=regularizers.l2(KER_REG_L2) if use_reg else None)) #last layer, activation imposed to sigmoid to interpret results as probabilities tn_model.add( TTN_SingleNode( bond_dim=1, #bond dim = 1 to get a single value activation= 'sigmoid', #sigmoid activation to obtain a probability n_contraction=n_contr, kernel_regularizer=regularizers.l2(KER_REG_L2) if use_reg else None)) return tn_model
def transition_block(x, alpha): filters = int(K.int_shape(x)[-1] * alpha) x = Conv2D(filters, 1, strides=2, use_bias=False)(x) x = BatchNormalization(epsilon=1.001e-5)(x) x = Activation('relu')(x) return x
def build_model(image_size, n_classes, mode='training', l2_regularization=0.0, min_scale=0.1, max_scale=0.9, scales=None, aspect_ratios_global=[0.5, 1.0, 2.0], aspect_ratios_per_layer=None, two_boxes_for_ar1=True, steps=None, offsets=None, clip_boxes=False, variances=[1.0, 1.0, 1.0, 1.0], coords='centroids', normalize_coords=False, subtract_mean=None, divide_by_stddev=None, swap_channels=False, confidence_thresh=0.01, iou_threshold=0.45, top_k=200, nms_max_output_size=400, return_predictor_sizes=False): ''' Build a Keras model with SSD architecture, see references. The model consists of convolutional feature layers and a number of convolutional predictor layers that take their input from different feature layers. The model is fully convolutional. The implementation found here is a smaller version of the original architecture used in the paper (where the base network consists of a modified VGG-16 extended by a few convolutional feature layers), but of course it could easily be changed to an arbitrarily large SSD architecture by following the general design pattern used here. This implementation has 7 convolutional layers and 4 convolutional predictor layers that take their input from layers 4, 5, 6, and 7, respectively. Most of the arguments that this function takes are only needed for the anchor box layers. In case you're training the network, the parameters passed here must be the same as the ones used to set up `SSDBoxEncoder`. In case you're loading trained weights, the parameters passed here must be the same as the ones used to produce the trained weights. Some of these arguments are explained in more detail in the documentation of the `SSDBoxEncoder` class. Note: Requires Keras v2.0 or later. Training currently works only with the TensorFlow backend (v1.0 or later). Arguments: image_size (tuple): The input image size in the format `(height, width, channels)`. n_classes (int): The number of positive classes, e.g. 20 for Pascal VOC, 80 for MS COCO. mode (str, optional): One of 'training', 'inference' and 'inference_fast'. In 'training' mode, the model outputs the raw prediction tensor, while in 'inference' and 'inference_fast' modes, the raw predictions are decoded into absolute coordinates and filtered via confidence thresholding, non-maximum suppression, and top-k filtering. The difference between latter two modes is that 'inference' follows the exact procedure of the original Caffe implementation, while 'inference_fast' uses a faster prediction decoding procedure. l2_regularization (float, optional): The L2-regularization rate. Applies to all convolutional layers. min_scale (float, optional): The smallest scaling factor for the size of the anchor boxes as a fraction of the shorter side of the input images. max_scale (float, optional): The largest scaling factor for the size of the anchor boxes as a fraction of the shorter side of the input images. All scaling factors between the smallest and the largest will be linearly interpolated. Note that the second to last of the linearly interpolated scaling factors will actually be the scaling factor for the last predictor layer, while the last scaling factor is used for the second box for aspect ratio 1 in the last predictor layer if `two_boxes_for_ar1` is `True`. scales (list, optional): A list of floats containing scaling factors per convolutional predictor layer. This list must be one element longer than the number of predictor layers. The first `k` elements are the scaling factors for the `k` predictor layers, while the last element is used for the second box for aspect ratio 1 in the last predictor layer if `two_boxes_for_ar1` is `True`. This additional last scaling factor must be passed either way, even if it is not being used. If a list is passed, this argument overrides `min_scale` and `max_scale`. All scaling factors must be greater than zero. aspect_ratios_global (list, optional): The list of aspect ratios for which anchor boxes are to be generated. This list is valid for all predictor layers. The original implementation uses more aspect ratios for some predictor layers and fewer for others. If you want to do that, too, then use the next argument instead. aspect_ratios_per_layer (list, optional): A list containing one aspect ratio list for each predictor layer. This allows you to set the aspect ratios for each predictor layer individually. If a list is passed, it overrides `aspect_ratios_global`. two_boxes_for_ar1 (bool, optional): Only relevant for aspect ratio lists that contain 1. Will be ignored otherwise. If `True`, two anchor boxes will be generated for aspect ratio 1. The first will be generated using the scaling factor for the respective layer, the second one will be generated using geometric mean of said scaling factor and next bigger scaling factor. steps (list, optional): `None` or a list with as many elements as there are predictor layers. The elements can be either ints/floats or tuples of two ints/floats. These numbers represent for each predictor layer how many pixels apart the anchor box center points should be vertically and horizontally along the spatial grid over the image. If the list contains ints/floats, then that value will be used for both spatial dimensions. If the list contains tuples of two ints/floats, then they represent `(step_height, step_width)`. If no steps are provided, then they will be computed such that the anchor box center points will form an equidistant grid within the image dimensions. offsets (list, optional): `None` or a list with as many elements as there are predictor layers. The elements can be either floats or tuples of two floats. These numbers represent for each predictor layer how many pixels from the top and left boarders of the image the top-most and left-most anchor box center points should be as a fraction of `steps`. The last bit is important: The offsets are not absolute pixel values, but fractions of the step size specified in the `steps` argument. If the list contains floats, then that value will be used for both spatial dimensions. If the list contains tuples of two floats, then they represent `(vertical_offset, horizontal_offset)`. If no offsets are provided, then they will default to 0.5 of the step size, which is also the recommended setting. clip_boxes (bool, optional): If `True`, clips the anchor box coordinates to stay within image boundaries. variances (list, optional): A list of 4 floats >0. The anchor box offset for each coordinate will be divided by its respective variance value. coords (str, optional): The box coordinate format to be used internally by the model (i.e. this is not the input format of the ground truth labels). Can be either 'centroids' for the format `(cx, cy, w, h)` (box center coordinates, width, and height), 'minmax' for the format `(xmin, xmax, ymin, ymax)`, or 'corners' for the format `(xmin, ymin, xmax, ymax)`. normalize_coords (bool, optional): Set to `True` if the model is supposed to use relative instead of absolute coordinates, i.e. if the model predicts box coordinates within [0,1] instead of absolute coordinates. subtract_mean (array-like, optional): `None` or an array-like object of integers or floating point values of any shape that is broadcast-compatible with the image shape. The elements of this array will be subtracted from the image pixel intensity values. For example, pass a list of three integers to perform per-channel mean normalization for color images. divide_by_stddev (array-like, optional): `None` or an array-like object of non-zero integers or floating point values of any shape that is broadcast-compatible with the image shape. The image pixel intensity values will be divided by the elements of this array. For example, pass a list of three integers to perform per-channel standard deviation normalization for color images. swap_channels (list, optional): Either `False` or a list of integers representing the desired order in which the input image channels should be swapped. confidence_thresh (float, optional): A float in [0,1), the minimum classification confidence in a specific positive class in order to be considered for the non-maximum suppression stage for the respective class. A lower value will result in a larger part of the selection process being done by the non-maximum suppression stage, while a larger value will result in a larger part of the selection process happening in the confidence thresholding stage. iou_threshold (float, optional): A float in [0,1]. All boxes that have a Jaccard similarity of greater than `iou_threshold` with a locally maximal box will be removed from the set of predictions for a given class, where 'maximal' refers to the box's confidence score. top_k (int, optional): The number of highest scoring predictions to be kept for each batch item after the non-maximum suppression stage. nms_max_output_size (int, optional): The maximal number of predictions that will be left over after the NMS stage. return_predictor_sizes (bool, optional): If `True`, this function not only returns the model, but also a list containing the spatial dimensions of the predictor layers. This isn't strictly necessary since you can always get their sizes easily via the Keras API, but it's convenient and less error-prone to get them this way. They are only relevant for training anyway (SSDBoxEncoder needs to know the spatial dimensions of the predictor layers), for inference you don't need them. Returns: model: The Keras SSD model. predictor_sizes (optional): A Numpy array containing the `(height, width)` portion of the output tensor shape for each convolutional predictor layer. During training, the generator function needs this in order to transform the ground truth labels into tensors of identical structure as the output tensors of the model, which is in turn needed for the cost function. References: https://arxiv.org/abs/1512.02325v5 ''' n_predictor_layers = 4 # The number of predictor conv layers in the network n_classes += 1 # Account for the background class. l2_reg = l2_regularization # Make the internal name shorter. img_height, img_width, img_channels = image_size[0], image_size[1], image_size[2] ############################################################################ # Get a few exceptions out of the way. ############################################################################ if aspect_ratios_global is None and aspect_ratios_per_layer is None: raise ValueError("`aspect_ratios_global` and `aspect_ratios_per_layer` cannot both be None. At least one needs to be specified.") if aspect_ratios_per_layer: if len(aspect_ratios_per_layer) != n_predictor_layers: raise ValueError("It must be either aspect_ratios_per_layer is None or len(aspect_ratios_per_layer) == {}, but len(aspect_ratios_per_layer) == {}.".format(n_predictor_layers, len(aspect_ratios_per_layer))) if (min_scale is None or max_scale is None) and scales is None: raise ValueError("Either `min_scale` and `max_scale` or `scales` need to be specified.") if scales: if len(scales) != n_predictor_layers+1: raise ValueError("It must be either scales is None or len(scales) == {}, but len(scales) == {}.".format(n_predictor_layers+1, len(scales))) else: # If no explicit list of scaling factors was passed, compute the list of scaling factors from `min_scale` and `max_scale` scales = np.linspace(min_scale, max_scale, n_predictor_layers+1) if len(variances) != 4: # We need one variance value for each of the four box coordinates raise ValueError("4 variance values must be pased, but {} values were received.".format(len(variances))) variances = np.array(variances) if np.any(variances <= 0): raise ValueError("All variances must be >0, but the variances given are {}".format(variances)) if (not (steps is None)) and (len(steps) != n_predictor_layers): raise ValueError("You must provide at least one step value per predictor layer.") if (not (offsets is None)) and (len(offsets) != n_predictor_layers): raise ValueError("You must provide at least one offset value per predictor layer.") ############################################################################ # Compute the anchor box parameters. ############################################################################ # Set the aspect ratios for each predictor layer. These are only needed for the anchor box layers. if aspect_ratios_per_layer: aspect_ratios = aspect_ratios_per_layer else: aspect_ratios = [aspect_ratios_global] * n_predictor_layers # Compute the number of boxes to be predicted per cell for each predictor layer. # We need this so that we know how many channels the predictor layers need to have. if aspect_ratios_per_layer: n_boxes = [] for ar in aspect_ratios_per_layer: if (1 in ar) & two_boxes_for_ar1: n_boxes.append(len(ar) + 1) # +1 for the second box for aspect ratio 1 else: n_boxes.append(len(ar)) else: # If only a global aspect ratio list was passed, then the number of boxes is the same for each predictor layer if (1 in aspect_ratios_global) & two_boxes_for_ar1: n_boxes = len(aspect_ratios_global) + 1 else: n_boxes = len(aspect_ratios_global) n_boxes = [n_boxes] * n_predictor_layers if steps is None: steps = [None] * n_predictor_layers if offsets is None: offsets = [None] * n_predictor_layers ############################################################################ # Define functions for the Lambda layers below. ############################################################################ def identity_layer(tensor): return tensor def input_mean_normalization(tensor): return tensor - np.array(subtract_mean) def input_stddev_normalization(tensor): return tensor / np.array(divide_by_stddev) #def input_channel_swap(tensor): # if len(swap_channels) == 3: # return K.stack([tensor[...,swap_channels[0]], tensor[...,swap_channels[1]], tensor[...,swap_channels[2]]], axis=-1) # elif len(swap_channels) == 4: # return K.stack([tensor[...,swap_channels[0]], tensor[...,swap_channels[1]], tensor[...,swap_channels[2]], tensor[...,swap_channels[3]]], axis=-1) ############################################################################ # Build the network. ############################################################################ x = Input(shape=(img_height, img_width, img_channels)) # The following identity layer is only needed so that the subsequent lambda layers can be optional. x1 = Lambda(identity_layer, output_shape=(img_height, img_width, img_channels), name='identity_layer')(x) if not (subtract_mean is None): x1 = Lambda(input_mean_normalization, output_shape=(img_height, img_width, img_channels), name='input_mean_normalization')(x1) if not (divide_by_stddev is None): x1 = Lambda(input_stddev_normalization, output_shape=(img_height, img_width, img_channels), name='input_stddev_normalization')(x1) #if swap_channels: #REMOVED FOR TFLITE # x1 = Lambda(input_channel_swap, output_shape=(img_height, img_width, img_channels), name='input_channel_swap')(x1) conv1 = Conv2D(32, (5, 5), strides=(2, 2), padding="same", kernel_initializer='he_normal', kernel_regularizer=l2(l2_reg), name='conv1')(x1) conv1 = BatchNormalization(axis=3, momentum=0.99, name='bn1')(conv1) # Tensorflow uses filter format [filter_height, filter_width, in_channels, out_channels], hence axis = 3 conv1 = MaxPooling2D(pool_size=(3, 3), strides=(2, 2), padding='same', name='pool1')(conv1) conv2 = QuantConv2D(48, (3, 3), strides=(1, 1), padding="same", kernel_initializer='glorot_normal', use_bias=False, name='conv2', **kwargs)(conv1) conv2 = MaxPooling2D(pool_size=(3, 3), strides=(2, 2), name='pool2')(conv2) conv2 = BatchNormalization(axis=3, momentum=0.99, name='bn2')(conv2) conv3 = QuantConv2D(64, (3, 3), strides=(1, 1), padding="same", kernel_initializer='glorot_normal', use_bias=False, name='conv3', **kwargs)(conv2) #conv3 = MaxPooling2D(pool_size=(3, 3), strides=(2, 2), name='pool3')(conv3) conv3 = BatchNormalization(axis=3, momentum=0.99, name='bn3')(conv3) #Conv1,2,3 are for feature extraction and downsampling #Conv4,5,6,7 are the pre-detection feature maps conv4 = QuantConv2D(64, (3, 3), strides=(1, 1), padding="same", kernel_initializer='glorot_normal', use_bias=False, name='conv4', **kwargs)(conv3) conv4 = MaxPooling2D(pool_size=(3, 3), strides=(2, 2), name='pool4')(conv4) conv4 = BatchNormalization(axis=3, momentum=0.99, name='bn4')(conv4) conv5 = QuantConv2D(48, (3, 3), strides=(1, 1), padding="same", kernel_initializer='glorot_normal', use_bias=False, name='conv5', **kwargs)(conv4) conv5 = MaxPooling2D(pool_size=(3, 3), strides=(2, 2), name='pool5')(conv5) conv5 = BatchNormalization(axis=3, momentum=0.99, name='bn5')(conv5) conv6 = QuantConv2D(48, (3, 3), strides=(1, 1), padding="same", kernel_initializer='glorot_normal', use_bias=False, name='conv6', **kwargs)(conv5) conv6 = MaxPooling2D(pool_size=(3, 3), strides=(2, 2), name='pool6')(conv6) conv6 = BatchNormalization(axis=3, momentum=0.99, name='bn6')(conv6) conv7 = QuantConv2D(32, (3, 3), strides=(1, 1), padding="same", kernel_initializer='glorot_normal', use_bias=False, name='conv7', **kwargs)(conv6) conv7 = BatchNormalization(axis=3, momentum=0.99, name='bn7')(conv7) # The next part is to add the convolutional predictor layers on top of the base network # that we defined above. Note that I use the term "base network" differently than the paper does. # To me, the base network is everything that is not convolutional predictor layers or anchor # box layers. In this case we'll have four predictor layers, but of course you could # easily rewrite this into an arbitrarily deep base network and add an arbitrary number of # predictor layers on top of the base network by simply following the pattern shown here. # Build the convolutional predictor layers on top of conv layers 4, 5, 6, and 7. # We build two predictor layers on top of each of these layers: One for class prediction (classification), one for box coordinate prediction (localization) # We precidt `n_classes` confidence values for each box, hence the `classes` predictors have depth `n_boxes * n_classes` # We predict 4 box coordinates for each box, hence the `boxes` predictors have depth `n_boxes * 4` # Output shape of `classes`: `(batch, height, width, n_boxes * n_classes)` classes4 = Conv2D(n_boxes[0] * n_classes, (3, 3), strides=(1, 1), padding="same", kernel_initializer='he_normal', kernel_regularizer=l2(l2_reg), name='classes4')(conv4) classes5 = Conv2D(n_boxes[1] * n_classes, (3, 3), strides=(1, 1), padding="same", kernel_initializer='he_normal', kernel_regularizer=l2(l2_reg), name='classes5')(conv5) classes6 = Conv2D(n_boxes[2] * n_classes, (3, 3), strides=(1, 1), padding="same", kernel_initializer='he_normal', kernel_regularizer=l2(l2_reg), name='classes6')(conv6) classes7 = Conv2D(n_boxes[3] * n_classes, (3, 3), strides=(1, 1), padding="same", kernel_initializer='he_normal', kernel_regularizer=l2(l2_reg), name='classes7')(conv7) # Output shape of `boxes`: `(batch, height, width, n_boxes * 4)` boxes4 = Conv2D(n_boxes[0] * 4, (3, 3), strides=(1, 1), padding="same", kernel_initializer='he_normal', kernel_regularizer=l2(l2_reg), name='boxes4')(conv4) boxes5 = Conv2D(n_boxes[1] * 4, (3, 3), strides=(1, 1), padding="same", kernel_initializer='he_normal', kernel_regularizer=l2(l2_reg), name='boxes5')(conv5) boxes6 = Conv2D(n_boxes[2] * 4, (3, 3), strides=(1, 1), padding="same", kernel_initializer='he_normal', kernel_regularizer=l2(l2_reg), name='boxes6')(conv6) boxes7 = Conv2D(n_boxes[3] * 4, (3, 3), strides=(1, 1), padding="same", kernel_initializer='he_normal', kernel_regularizer=l2(l2_reg), name='boxes7')(conv7) # Generate the anchor boxes # Output shape of `anchors`: `(batch, height, width, n_boxes, 8)` anchors4 = AnchorBoxes(img_height, img_width, this_scale=scales[0], next_scale=scales[1], aspect_ratios=aspect_ratios[0], two_boxes_for_ar1=two_boxes_for_ar1, this_steps=steps[0], this_offsets=offsets[0], clip_boxes=clip_boxes, variances=variances, coords=coords, normalize_coords=normalize_coords, name='anchors4')(boxes4) anchors5 = AnchorBoxes(img_height, img_width, this_scale=scales[1], next_scale=scales[2], aspect_ratios=aspect_ratios[1], two_boxes_for_ar1=two_boxes_for_ar1, this_steps=steps[1], this_offsets=offsets[1], clip_boxes=clip_boxes, variances=variances, coords=coords, normalize_coords=normalize_coords, name='anchors5')(boxes5) anchors6 = AnchorBoxes(img_height, img_width, this_scale=scales[2], next_scale=scales[3], aspect_ratios=aspect_ratios[2], two_boxes_for_ar1=two_boxes_for_ar1, this_steps=steps[2], this_offsets=offsets[2], clip_boxes=clip_boxes, variances=variances, coords=coords, normalize_coords=normalize_coords, name='anchors6')(boxes6) anchors7 = AnchorBoxes(img_height, img_width, this_scale=scales[3], next_scale=scales[4], aspect_ratios=aspect_ratios[3], two_boxes_for_ar1=two_boxes_for_ar1, this_steps=steps[3], this_offsets=offsets[3], clip_boxes=clip_boxes, variances=variances, coords=coords, normalize_coords=normalize_coords, name='anchors7')(boxes7) # Reshape the class predictions, yielding 3D tensors of shape `(batch, height * width * n_boxes, n_classes)` # We want the classes isolated in the last axis to perform softmax on them #Shape inference is different for keras.layers and tf.keras.layers (-1), check documentation #So I had to manually input the intended shape of the reshape #cba = classes, boxes, anchors SHAPE: shape will be reused later anyways cba_4 = classes4.shape[1]*classes4.shape[2]*n_boxes[0] cba_5 = classes5.shape[1]*classes5.shape[2]*n_boxes[1] cba_6 = classes6.shape[1]*classes6.shape[2]*n_boxes[2] cba_7 = classes7.shape[1]*classes7.shape[2]*n_boxes[3] classes4_reshaped = Reshape((cba_4, n_classes), name='classes4_reshape')(classes4) classes5_reshaped = Reshape((cba_5, n_classes), name='classes5_reshape')(classes5) classes6_reshaped = Reshape((cba_6, n_classes), name='classes6_reshape')(classes6) classes7_reshaped = Reshape((cba_7, n_classes), name='classes7_reshape')(classes7) # Reshape the box coordinate predictions, yielding 3D tensors of shape `(batch, height * width * n_boxes, 4)` #shape for classes_reshaped is SAME with boxes EXCEPT for n_classes and anchors so NO NEED TO RECOMPUTE # We want the four box coordinates isolated in the last axis to compute the smooth L1 loss boxes4_reshaped = Reshape((cba_4, 4), name='boxes4_reshape')(boxes4) boxes5_reshaped = Reshape((cba_5, 4), name='boxes5_reshape')(boxes5) boxes6_reshaped = Reshape((cba_6, 4), name='boxes6_reshape')(boxes6) boxes7_reshaped = Reshape((cba_7, 4), name='boxes7_reshape')(boxes7) # Reshape the anchor box tensors, yielding 3D tensors of shape `(batch, height * width * n_boxes, 8)` anchors4_reshaped = Reshape((cba_4, 8), name='anchors4_reshape')(anchors4) anchors5_reshaped = Reshape((cba_5, 8), name='anchors5_reshape')(anchors5) anchors6_reshaped = Reshape((cba_6, 8), name='anchors6_reshape')(anchors6) anchors7_reshaped = Reshape((cba_7, 8), name='anchors7_reshape')(anchors7) # Concatenate the predictions from the different layers and the assosciated anchor box tensors # Axis 0 (batch) and axis 2 (n_classes or 4, respectively) are identical for all layer predictions, # so we want to concatenate along axis 1 # Output shape of `classes_concat`: (batch, n_boxes_total, n_classes) classes_concat = Concatenate(axis=1, name='classes_concat')([classes4_reshaped, classes5_reshaped, classes6_reshaped, classes7_reshaped]) # Output shape of `boxes_concat`: (batch, n_boxes_total, 4) boxes_concat = Concatenate(axis=1, name='boxes_concat')([boxes4_reshaped, boxes5_reshaped, boxes6_reshaped, boxes7_reshaped]) # Output shape of `anchors_concat`: (batch, n_boxes_total, 8) anchors_concat = Concatenate(axis=1, name='anchors_concat')([anchors4_reshaped, anchors5_reshaped, anchors6_reshaped, anchors7_reshaped]) # The box coordinate predictions will go into the loss function just the way they are, # but for the class predictions, we'll apply a softmax activation layer first classes_softmax = Activation('softmax', name='classes_softmax')(classes_concat) # Concatenate the class and box coordinate predictions and the anchors to one large predictions tensor # Output shape of `predictions`: (batch, n_boxes_total, n_classes + 4 + 8) predictions = Concatenate(axis=2, name='predictions')([classes_softmax, boxes_concat, anchors_concat]) if mode == 'training': model = Model(inputs=x, outputs=predictions) elif mode == 'inference': decoded_predictions = DecodeDetections(confidence_thresh=confidence_thresh, iou_threshold=iou_threshold, top_k=top_k, nms_max_output_size=nms_max_output_size, coords=coords, normalize_coords=normalize_coords, img_height=img_height, img_width=img_width, name='decoded_predictions')(predictions) model = Model(inputs=x, outputs=decoded_predictions) elif mode == 'inference_fast': decoded_predictions = DecodeDetectionsFast(confidence_thresh=confidence_thresh, iou_threshold=iou_threshold, top_k=top_k, nms_max_output_size=nms_max_output_size, coords=coords, normalize_coords=normalize_coords, img_height=img_height, img_width=img_width, name='decoded_predictions')(predictions) model = Model(inputs=x, outputs=decoded_predictions) else: raise ValueError("`mode` must be one of 'training', 'inference' or 'inference_fast', but received '{}'.".format(mode)) if return_predictor_sizes: # The spatial dimensions are the same for the `classes` and `boxes` predictor layers. predictor_sizes = np.array([classes4._keras_shape[1:3], classes5._keras_shape[1:3], classes6._keras_shape[1:3], classes7._keras_shape[1:3]]) return model, predictor_sizes else: return model
y = raw_wine.target print(X.shape) print(set(y)) y_hot = to_categorical(y) X_tn, X_te, y_tn, y_te = train_test_split(X, y_hot, random_state=0) n_feat = X_tn.shape[1] n_class = len(set(y)) epo = 30 model = Sequential() model.add(Dense(20, input_dim=n_feat)) # output_dim, input_dim model.add(BatchNormalization()) model.add(Activation('relu')) model.add(Dense(n_class)) # output_dim model.add(Activation('softmax')) model.summary() model.compile(loss='categorical_crossentropy', optimizer='adam', metrics=['accuracy']) # 이진형 : binary_crossentropy hist = model.fit(X_tn, y_tn, epochs=epo, batch_size=5) print(model.evaluate(X_tn, y_tn)[1]) print(model.evaluate(X_te, y_te)[1]) epoch = np.arange(1, epo + 1)
layer_sizes = [32, 64, 128] conv_layers = [1, 2, 3] for conv_layer in conv_layers: for layer_size in layer_sizes: for dense_layer in dense_layers: NAME = "{}--conv-{}-nodes-{}-dense-{}".format( conv_layer, layer_size, dense_layer, int(time.time())) tensorboard = TensorBoard(log_dir='logs\{}'.format( NAME)) # 'tensorboard --logdir=logs' shows tensorboard print(NAME) model = Sequential() model.add(Conv2D(layer_size, (3, 3), input_shape=X.shape[1:])) model.add(Activation("relu")) model.add(MaxPooling2D(pool_size=(2, 2))) for l in range(conv_layer - 1): model.add(Conv2D(layer_size, (3, 3))) model.add(Activation("relu")) model.add(MaxPooling2D(pool_size=(2, 2))) model.add(Flatten( )) # this converts our 3D feature maps to 1D feature vectors for l in range(dense_layer): model.add(Dense(layer_size)) model.add(Activation("relu")) model.add(Dense(1))
ENV_NAME = 'CartPole-v0' # Get the environment and extract the number of actions. env = gym.make(ENV_NAME) np.random.seed(123) env.seed(123) nb_actions = env.action_space.n obs_dim = env.observation_space.shape[0] # Option 1 : Simple model model = Sequential() model.add(Flatten(input_shape=(1, ) + env.observation_space.shape)) model.add(Dense(nb_actions)) model.add(Activation('softmax')) # Option 2: deep network # model = Sequential() # model.add(Flatten(input_shape=(1,) + env.observation_space.shape)) # model.add(Dense(16)) # model.add(Activation('relu')) # model.add(Dense(16)) # model.add(Activation('relu')) # model.add(Dense(16)) # model.add(Activation('relu')) # model.add(Dense(nb_actions)) # model.add(Activation('softmax')) print(model.summary())
#splitting data x_train, x_test, y_train, y_test = train_test_split(x, y, test_size = 0.15) #0.15 #means allocating 15% of the data to be testing data #TRAIN AND EVALUATE LINEAR REGRESSION MODEL LinReg_model = LinearRegression() LinReg_model.fit(x_train, y_train) accuracy_LinReg = LinReg_model.score(x_train, y_train) print (accuracy_LinReg) # USING ARTIFICIAL NEURAL NETWORK ANN_model = keras.Sequential() ANN_model.add(Dense(50, input_dim = 7)) ANN_model.add(Activation('relu')) ANN_model.add(Dense(150)) ANN_model.add(Activation('relu')) ANN_model.add(Dropout(0.5)) ANN_model.add(Dense(150)) ANN_model.add(Activation('relu')) ANN_model.add(Dropout(0.5)) ANN_model.add(Dense(50)) ANN_model.add(Activation('linear')) ANN_model.add(Dense(1)) ANN_model.compile(loss = 'mse', optimizer = 'adam') ANN_model.summary()
import pickle import numpy as np DATADIR = "/content/drive/My Drive/Google20/" pickle_in = open(DATADIR + "datasetX.pickle", "rb") X = pickle.load(pickle_in) X = X / 255.0 pickle_in = open(DATADIR + "datasety.pickle", "rb") y = pickle.load(pickle_in) y = np.array(y) model = Sequential() model.add(Conv2D(32, (5, 5), input_shape=X.shape[1:])) model.add(Activation('relu')) model.add(Conv2D(64, (3, 3))) model.add(Activation('relu')) model.add(Conv2D(64, (3, 3))) model.add(Activation('relu')) model.add(MaxPooling2D(pool_size=(2, 2))) model.add(Flatten()) model.add(Dense(64)) model.add(Activation('relu')) model.add(Dense(5)) model.add(Activation('sigmoid')) tensorboard = TensorBoard(log_dir=DATADIR + "logs/{}".format("Music Tron 3000")) opt = Adam()
def mini_XCEPTION(input_shape, num_classes, l2_regularization=0.01): regularization = l2(l2_regularization) # base img_input = Input(input_shape) x = Conv2D(8, (3, 3), strides=(1, 1), kernel_regularizer=regularization, use_bias=False)(img_input) x = BatchNormalization()(x) x = Activation('relu')(x) x = Conv2D(8, (3, 3), strides=(1, 1), kernel_regularizer=regularization, use_bias=False)(x) x = BatchNormalization()(x) x = Activation('relu')(x) # module 1 residual = Conv2D(16, (1, 1), strides=(2, 2), padding='same', use_bias=False)(x) residual = BatchNormalization()(residual) x = SeparableConv2D(16, (3, 3), padding='same', kernel_regularizer=regularization, use_bias=False)(x) x = BatchNormalization()(x) x = Activation('relu')(x) x = SeparableConv2D(16, (3, 3), padding='same', kernel_regularizer=regularization, use_bias=False)(x) x = BatchNormalization()(x) x = MaxPooling2D((3, 3), strides=(2, 2), padding='same')(x) x = layers.add([x, residual]) # module 2 residual = Conv2D(32, (1, 1), strides=(2, 2), padding='same', use_bias=False)(x) residual = BatchNormalization()(residual) x = SeparableConv2D(32, (3, 3), padding='same', kernel_regularizer=regularization, use_bias=False)(x) x = BatchNormalization()(x) x = Activation('relu')(x) x = SeparableConv2D(32, (3, 3), padding='same', kernel_regularizer=regularization, use_bias=False)(x) x = BatchNormalization()(x) x = MaxPooling2D((3, 3), strides=(2, 2), padding='same')(x) x = layers.add([x, residual]) # module 3 residual = Conv2D(64, (1, 1), strides=(2, 2), padding='same', use_bias=False)(x) residual = BatchNormalization()(residual) x = SeparableConv2D(64, (3, 3), padding='same', kernel_regularizer=regularization, use_bias=False)(x) x = BatchNormalization()(x) x = Activation('relu')(x) x = SeparableConv2D(64, (3, 3), padding='same', kernel_regularizer=regularization, use_bias=False)(x) x = BatchNormalization()(x) x = MaxPooling2D((3, 3), strides=(2, 2), padding='same')(x) x = layers.add([x, residual]) # module 4 residual = Conv2D(128, (1, 1), strides=(2, 2), padding='same', use_bias=False)(x) residual = BatchNormalization()(residual) x = SeparableConv2D(128, (3, 3), padding='same', kernel_regularizer=regularization, use_bias=False)(x) x = BatchNormalization()(x) x = Activation('relu')(x) x = SeparableConv2D(128, (3, 3), padding='same', kernel_regularizer=regularization, use_bias=False)(x) x = BatchNormalization()(x) x = MaxPooling2D((3, 3), strides=(2, 2), padding='same')(x) x = layers.add([x, residual]) x = Conv2D( num_classes, (3, 3), # kernel_regularizer=regularization, padding='same')(x) x = GlobalAveragePooling2D()(x) output = Dense(30)(x) model = Model(img_input, output) return model
x_test = x_test.reshape(x_test.shape[0], x_test.shape[1], x_test.shape[2], 1) x_train = x_train / 255.0 x_test = x_test / 255.0 y_train = to_categorical(y_train, NUM_CLASSES) y_test = to_categorical(y_test, NUM_CLASSES) print("x_train.shape = {}, y_train.shape = {}".format(x_train.shape, y_train.shape)) print("x_test.shape = {}, y_test.shape = {}".format(x_test.shape, y_test.shape)) inputs = Input(shape=(28, 28, 1), name='input') x = Conv2D(24, kernel_size=(6, 6), strides=1)(inputs) x = BatchNormalization(scale=False, beta_initializer=Constant(0.01))(x) x = Activation('relu')(x) x = Dropout(rate=0.25)(x) x = Conv2D(48, kernel_size=(5, 5), strides=2)(x) x = BatchNormalization(scale=False, beta_initializer=Constant(0.01))(x) x = Activation('relu')(x) x = Dropout(rate=0.25)(x) x = Conv2D(64, kernel_size=(4, 4), strides=2)(x) x = BatchNormalization(scale=False, beta_initializer=Constant(0.01))(x) x = Activation('relu')(x) x = Dropout(rate=0.25)(x) x = Flatten()(x) x = Dense(200)(x) x = BatchNormalization(scale=False, beta_initializer=Constant(0.01))(x)
print("starting") import tensorflow as tf from tensorflow.keras.models import Sequential from tensorflow.keras.layers import Dense, Dropout, Activation model1 = Sequential([ Dense(256, input_shape=(24, )), Activation('relu'), Dense(128), Activation('relu'), Dense(128), Activation('relu'), Dense(64), Activation('relu'), Dense(2), Activation('softmax') ]) print(model1.summary())
def DeepConvNet(nb_classes, Chans = 64, Samples = 256, dropoutRate = 0.5): """ Keras implementation of the Deep Convolutional Network as described in Schirrmeister et. al. (2017), Human Brain Mapping. This implementation assumes the input is a 2-second EEG signal sampled at 128Hz, as opposed to signals sampled at 250Hz as described in the original paper. We also perform temporal convolutions of length (1, 5) as opposed to (1, 10) due to this sampling rate difference. Note that we use the max_norm constraint on all convolutional layers, as well as the classification layer. We also change the defaults for the BatchNormalization layer. We used this based on a personal communication with the original authors. ours original paper pool_size 1, 2 1, 3 strides 1, 2 1, 3 conv filters 1, 5 1, 10 Note that this implementation has not been verified by the original authors. """ # start the model input_main = Input((Chans, Samples, 1)) block1 = Conv2D(25, (1, 5), input_shape=(Chans, Samples, 1), kernel_constraint = max_norm(2., axis=(0,1,2)))(input_main) block1 = Conv2D(25, (Chans, 1), kernel_constraint = max_norm(2., axis=(0,1,2)))(block1) block1 = BatchNormalization(epsilon=1e-05, momentum=0.1)(block1) block1 = Activation('elu')(block1) block1 = MaxPooling2D(pool_size=(1, 2), strides=(1, 2))(block1) block1 = Dropout(dropoutRate)(block1) block2 = Conv2D(50, (1, 5), kernel_constraint = max_norm(2., axis=(0,1,2)))(block1) block2 = BatchNormalization(epsilon=1e-05, momentum=0.1)(block2) block2 = Activation('elu')(block2) block2 = MaxPooling2D(pool_size=(1, 2), strides=(1, 2))(block2) block2 = Dropout(dropoutRate)(block2) block3 = Conv2D(100, (1, 5), kernel_constraint = max_norm(2., axis=(0,1,2)))(block2) block3 = BatchNormalization(epsilon=1e-05, momentum=0.1)(block3) block3 = Activation('elu')(block3) block3 = MaxPooling2D(pool_size=(1, 2), strides=(1, 2))(block3) block3 = Dropout(dropoutRate)(block3) block4 = Conv2D(200, (1, 5), kernel_constraint = max_norm(2., axis=(0,1,2)))(block3) block4 = BatchNormalization(epsilon=1e-05, momentum=0.1)(block4) block4 = Activation('elu')(block4) block4 = MaxPooling2D(pool_size=(1, 2), strides=(1, 2))(block4) block4 = Dropout(dropoutRate)(block4) flatten = Flatten()(block4) dense = Dense(nb_classes, kernel_constraint = max_norm(0.5))(flatten) softmax = Activation('softmax')(dense) return Model(inputs=input_main, outputs=softmax)
def DBMA(band, imx, ncla1): input1 = Input(shape=(imx, imx, band, 1)) ## spectral branch conv11 = Conv3D(24, kernel_size=(1, 1, 7), strides=(1, 1, 2), padding='valid', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn12 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv12 = Conv3D(24, kernel_size=(1, 1, 7), strides=(1, 1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn13 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv13 = Conv3D(24, kernel_size=(1, 1, 7), strides=(1, 1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn14 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv14 = Conv3D(24, kernel_size=(1, 1, 7), strides=(1, 1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn15 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv15 = Conv3D(60, kernel_size=(1, 1, 4), strides=(1, 1, 1), padding='valid', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) fc11 = Dense(30, activation=None, kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) fc12 = Dense(60, activation=None, kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) ## spatial branch conv21 = Conv3D(24, kernel_size=(1, 1, band), strides=(1, 1, 1), padding='valid', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn22 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv22 = Conv3D(12, kernel_size=(3, 3, 1), strides=(1, 1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn23 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv23 = Conv3D(12, kernel_size=(3, 3, 1), strides=(1, 1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn24 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv24 = Conv3D(12, kernel_size=(3, 3, 1), strides=(1, 1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) bn25 = BatchNormalization(axis=-1, momentum=0.9, epsilon=0.001, center=True, scale=True, beta_initializer='zeros', gamma_initializer='ones', moving_mean_initializer='zeros', moving_variance_initializer='ones') conv25 = Conv3D(24, kernel_size=(3, 3, 1), strides=(1, 1, 1), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) conv26 = Conv3D(1, activation=None, kernel_size=(3, 3, 2), strides=(1, 1, 2), padding='same', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) fc = Dense(ncla1, activation='softmax', name='output1', kernel_initializer=RandomNormal(mean=0.0, stddev=0.01)) # spectral x1 = conv11(input1) x11 = bn12(x1) x11 = Activation('relu')(x11) x11 = conv12(x11) x12 = concatenate([x1, x11], axis=-1) x12 = bn13(x12) x12 = Activation('relu')(x12) x12 = conv13(x12) x13 = concatenate([x1, x11, x12], axis=-1) x13 = bn14(x13) x13 = Activation('relu')(x13) x13 = conv14(x13) x14 = concatenate([x1, x11, x12, x13], axis=-1) x14 = bn15(x14) x14 = Activation('relu')(x14) x14 = conv15(x14) x1_max = MaxPooling3D(pool_size=(7, 7, 1))(x14) x1_avg = AveragePooling3D(pool_size=(7, 7, 1))(x14) x1_max = fc11(x1_max) x1_max = fc12(x1_max) x1_avg = fc11(x1_avg) x1_avg = fc12(x1_avg) x1 = Add()([x1_max, x1_avg]) x1 = Activation('sigmoid')(x1) x1 = multiply([x1, x14]) x1 = GlobalAveragePooling3D()(x1) # spatial x2 = conv21(input1) x21 = bn22(x2) x21 = Activation('relu')(x21) x21 = conv22(x21) x22 = concatenate([x2, x21], axis=-1) x22 = bn23(x22) x22 = Activation('relu')(x22) x22 = conv23(x22) x23 = concatenate([x2, x21, x22], axis=-1) x23 = bn24(x23) x23 = Activation('relu')(x23) x23 = conv24(x23) x24 = concatenate([x2, x21, x22, x23], axis=-1) x24 = Reshape(target_shape=(7, 7, 60, 1))(x24) x2_max = MaxPooling3D(pool_size=(1, 1, 60))(x24) x2_avg = AveragePooling3D(pool_size=(1, 1, 60))(x24) x2_max = Reshape(target_shape=(7, 7, 1))(x2_max) x2_avg = Reshape(target_shape=(7, 7, 1))(x2_avg) x25 = concatenate([x2_max, x2_avg], axis=-1) x25 = Reshape(target_shape=(7, 7, 2, 1))(x25) x25 = conv26(x25) x25 = Activation('sigmoid')(x25) x2 = multiply([x24, x25]) x2 = Reshape(target_shape=(7, 7, 1, 60))(x2) x2 = GlobalAveragePooling3D()(x2) x = concatenate([x1, x2], axis=-1) pre = fc(x) model = Model(inputs=input1, outputs=pre) return model